BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a nail gun that drives a nail through, for example, the hole of a connection clasp and to a nail gun that can accurately drive nails into a desired drive position.
2. Description of the Related Art
A variety of different types of clasp fixing nail guns have been proposed. U.S. Pat. No. 5,193,730 discloses a nail gun that separates nails one at a time from a nail band and supplies the nail to a nail injection hole of the nosepiece. The nail tip is protruded from the end of the nosepiece before the nail gun drives the nail.
The nail gun further has a safety mechanism with a work-piece contact member, an intermediate lever, and an operation lever. The work-piece contact member extends from the nose of the nail gun to the base of the intermediate lever. When the trigger of the nail gun is pressed, the operation lever moves toward or away from an activation plunger, depending on the position of the work-piece contact member and the intermediate lever. That is, the work-piece contact member is raised into its lowermost position as long as the nose of the nail gun is not pressed against a work piece. If the trigger is pressed at this time, the intermediate lever pivots greatly and guides movement of the operation lever away from the activation plunger. On the other hand, when the nose of the nail gun is pressed against a work piece, the contact member is raised into its upper position. If the trigger is pulled at this time, pivoting movement of the intermediate lever is restricted so that the operation lever moves into contact with the activation plunger, thereby setting off a nail driving operation. In other words, the safety mechanism prevents the nail gun from firing when no work piece is present by changing the pivot path of the operation lever.
SUMMARY OF THE PRESENT INVENTION
It is conceivable to lengthen the stroke of the work-piece contact member, that is, the distance that the work-piece contact member can move, by increasing the length of the intermediate lever. However, the intermediate lever can only be lengthened within the movement range of the trigger. Therefore, it is difficult to lengthen the stroke of the work-piece contact member. As a result, the lower end of the work-piece contact member must always be positioned fairly near the nail ejection opening, even when the work-piece contact member is at its upper dead center. This makes it difficult to see the nail tip so that it is difficult to position the nail at the precise position where it is to be driven into the work piece.
Also, the intermediate lever and the operation lever are provided in a narrow space above the trigger and operate in a fairly complicated manner against urging force of springs. A slight error in component or position dimensions, abrasion caused by friction, or dust, dirt, and the like clinging to components could easily become the cause of misfires. As a result, reliability of the nail gun suffers.
It is an objective of the present invention to overcome the above-described problems and provide a nail gun that more easily allows visual confirmation of the nail tip location and that uses a simpler configuration, which improves reliability by helping prevent the danger of misfires.
In order to achieve the above-described objective, a nail gun according to the present invention includes a body; a nail ejection portion connected to the body and having a tip formed with a nail ejection hole; a magazine connected to the nail ejection portion, the magazine feeding nails one at a time to the ejection portion; a blade supported in the body capable of reciprocal movement in opposing first and second directions and, when activated, driven in the second direction to the nail ejection portion to strike a nail in the nail ejection portion and to eject the nail through the nail ejection hole; an activation switch having a protruding plunger, the activating switch activating the blade when the plunger is pressed inward; a trigger having a trigger pivot end and a trigger free end, the trigger being supported pivotably on the body at the trigger pivot end; a trigger arm positioned within the trigger, the trigger arm having a trigger-arm pivot end, a central portion, and a trigger-arm free end, the trigger-arm pivot end being pivotably disposed at a position between the plunger and the trigger free end, the central portion being disposed at a position adjacent to the plunger; a safety portion having a first-side end disposed in contact with the trigger-arm free end and a second-side end positioned near the nail ejection hole, the safety portion being supported capable of reciprocal movement in the first and second directions between an upper dead center and a lower dead center; and urging means for urging the safety portion into the upper dead center; wherein when the trigger is pivoted on the trigger pivot end, pivoting movement of the trigger moves the trigger-arm pivot end to press the central portion of the trigger arm into contact with the plunger and, with the plunger serving as a fulcrum, to press the trigger-arm free end in the second direction against the first-side end of the safety portion.
With this configuration, a long stroke can be achieved for the safety portion. Therefore, the lower end of the safety portion can be separated from the nail tip in the initial condition, so that whether the nail tip is properly set in the clasp hole can be visually confirmed with ease. That is, the position where nails will be driven into the work piece can be accurately set.
Also, only the trigger arm is provided within the trigger and the safety portion is configured from only the upper safety portion and the lower safety portion. Operations are more reliable because the configuration is so simple.
If movement of the safety portion in the second direction is obstructed when the trigger is pivoted on the trigger pivot end, then the first-side end of the safety portion contacted by the trigger-arm free end serves as a fulcrum around which the trigger arm pivots with movement of the trigger, whereupon the central portion presses the plunger inward so that the activation switch activates the blade.
As a result, a nail driving operation can be reliably performed.
BRIEF DESCRIPTION OF THE DRAWINGS
The above and other objects, features and advantages of the invention will become more apparent from reading the following description of the embodiments taken in connection with the accompanying drawings in which:
FIG. 1 is a cross-sectional side view showing a nail gun according to a first embodiment of the present invention;
FIG. 2 is a side view showing connected nails used in the nail gun of FIG. 1;
FIG. 3 is a cross-sectional view showing details of a safety portion and surrounding components of the nail gun in FIG. 1, while the trigger is not pulled;
FIG. 4 is front view showing a cam member of the safety portion;
FIG. 5 is a side view of the cam member of FIG. 4;
FIG. 6 is a back view of the cam member of FIG. 4;
FIG. 7 is a cross-sectional view taken along line VII—VII of FIG. 4;
FIG. 8 is a front view of the safety portion;
FIG. 9 is a cross-sectional view showing the trigger of the nail gun pulled while the nail gun is pressed against a work piece;
FIG. 10 is a cross-sectional view showing a nail driving operation;
FIG. 11 is a cross-sectional view showing the trigger of the nail gun pulled while no work piece obstructs downward movement of the safety portion;
FIG. 12 is a cross-sectional view showing the cam member pivoted by downward movement of the safety portion in the situation shown in FIG. 11;
FIG. 13 is a cross-sectional view showing a lower portion of the safety portion moving upward when pressed against a work piece while the cam member is pivoted as shown in FIG. 12;
FIG. 14 is a cross-sectional view showing a safety portion according to a second embodiment of the present invention;
FIG. 15 is a cross-sectional view showing disconnection of upper and lower portions of the safety portion of FIG. 14 when the trigger is pulled while nothing obstructs downward movement of the safety portion; and
FIG. 16 is a cross-sectional view showing the lower portion of the safety portion of FIG. 14 moving independently upward when pressed against a work piece while upper and lower portions are disconnected as shown in FIG. 15.
DETAILED DESCRIPTION OF THE EMBODIMENTS
Next, a nail gun according to a first embodiment of the present invention will be provided while referring to FIGS. 1 to 13. To facilitate explanation, the directional terms up, down, front, and rear will be used referring to orientation in which the nail gun is intended to be used and as indicated in FIG. 1.
As shown in FIG. 1, a nail gun 1 includes a nail ejection portion 5, a magazine 6, a drive portion 8, a trigger 11, and a safety portion 12. The magazine 6 houses connected nails 3 that are supplied to the nail ejection portion 5. As shown in FIG. 2, the connected nails 3 are arranged on a single plane, separated by a fixed distance, and connected by a connection band 3 a. Each nail 4 typically has a circular head 4 a at its upper end, a cylindrical body 4 b, and an acutely pointed tip 4 c. As shown in FIG. 1, the magazine 6 includes a feeder 14 and a feeder spring (not shown). The feeder 14 receives pressure from the feeder spring and feeds the nails 4 to the nail ejection portion 5, which is formed by a nosepiece 13 of the nail gun 1.
The nail ejection portion 5 is formed at its lower end with a nail ejection hole 5 a. The tip 4 c of the lead nail 4 within the nail ejection portion 5 protrudes downward out of the nail erection hole 5 a, so that the position of the nail tip 4 c can be visually confirmed with ease.
The drive portion 8 houses a blade 7. The blade 7 is capable of reciprocal movement in the drive portion 8 to drive nails supplied to the nail ejection portion 5 out from the ejection hole 5 a.
The nail gun 1 also includes a handle 9 and an activation switch 10. The handle 9 is held by the user to support the nail gun 1. The activation switch 10 is for controlling a nail driving operation of the nail gun 1. As shown in FIG. 3, the activation switch 10 includes a downward-protruding plunger 17 substantially at its center. The plunger 17 is supported capable of reciprocal movement in the vertical direction. While the plunger 17 is positioned at its lower dead center, the activation switch 10 is maintained OFF, so the nail gun 1 remains in a non-activated condition. However, as the plunger 17 moves from its lower dead center to its upper dead center, the activation switch 10 is turned ON, so that the nail gun 1 starts a nail driving operation.
As shown in FIG. 3, the trigger 11 is supported adjacent to the activation switch 10 on a pivot shaft 16 so as to be capable of pivotable movement centered on the pivot shaft 16. The user uses a finger of the hand he or she uses to hold the handle 9 to pull the trigger 11. The trigger 11 is provided with a support portion 18 that pivotably supports a trigger arm 19. The trigger arm 19 is supported in a posture with the central portion in contact with the tip of the plunger 17 and with the other end 19 a in contact on an upper end 12 a of the safety portion 12.
The safety portion 12 is supported capable of reciprocal movement, in parallel with the reciprocal movement direction of the blade 7, between upper and lower dead centers as guided by a nose 13, which configures the nail ejection portion 5. The safety portion 12 is configured from an upper safety portion 20, a cam member 21, and a lower safety portion 22.
The upper safety portion 20 has a substantial reversed L-shape, and includes the upper end 12 a, a vertical section 20 c, and a horizontal section 20 d. The upper end 12 a is disposed in contact with the underside of the free end 19 a of the trigger arm 19. A spring 15 is disposed beneath the horizontal section 20 d for constantly urging the safety portion 12 toward its upper dead center.
The lower safety portion 22 is supported capable of reciprocal movement in parallel with the reciprocal movement direction of the blade 7, as guided by pins 23, 24 provided in the nose 13. The lower safety portion 22 includes a lower end 12 b and an engagement recess portion 22 a. The lower end 12 b is located near the ejection opening 5 a of the nail ejection portion 5. When the safety portion 12 is in its upper dead center following the urging of the spring 15, the lower end 12 b is retracted above the nail tip 4 c as shown in FIG. 3. On the other hand, when the safety portion 12 is in its lower dead center, the lower end 12 b protrudes beyond the nail tip 4 c of the nail 4 in the nail ejection portion 5 as shown in FIG. 11. The engagement recess portion 22 a is provided in the upper portion of the lower safety portion 22 and includes an upper plate 22 b and a lower plate 22 c, wherein the upper plate 22 b protrudes further than the lower plate 22 c. A spring 25 is provided for constantly urging the lower safety portion 22 downward when the nail gun 1 is oriented as in the drawings. Said differently, when the nail gun 1 is oriented for driving a nail upward, for example, into a ceiling fixture, the spring 25 prevents the lower safety portion 22 from sagging downward.
The cam member 21 is pivotably supported on a shaft 20 a provided to a lower portion of the upper safety portion 20. As shown in FIGS. 4 to 8, the car portion 21 includes a lower end 21 a and two guide protrusions 21 b. As shown in FIG. 3, the lower end 21 a fits in the engagement recess portion 22 a of the lower safety portion 22. As shown in FIG. 4, the guide protrusions 21 b are provided symmetrically on either side of the cam portion 21. As shown in FIGS. 1 and 12, the guide protrusions 21 b fit in guide grooves 5 b provided in the side surfaces of the nail ejection portion 5. The guide grooves 5 b are formed in a diagonally extending shape, so that when the guide protrusions 21 b move downward in the guide grooves 5 b, the cam member 21 separates from the engagement recess portion 22 a as shown in FIG. 11.
Next, an explanation will be provided for operation of the nail gun 1. In this example, the nail gun 1 is used to fix in place a connection clasp 2 shown in FIG. 9. The connection clasp 3 is preformed with a hole 2 a. First, the nail tip 4 c protruding from the nail ejection hole 5 a is set directly into the hole 2 a of the connection clasp 2. Because the nail tip 4 c protrudes from the nail ejection hole 5 a, the nail tip 4 c can be easily aligned with the clasp hole 2 a. Once the nail tip 4 c is set, the lower end 12 b of the lower safety portion 22 presses against an upper surface 2 b of the clasp 2, so the safety portion 12 is prevented from moving downward.
Next, the user pulls the trigger 11 of the nail gun 1. When the user pulls the trigger 11, the trigger 11 pivots centered on the pivot shaft 16 toward the activation switch 10, that is, from the orientation shown in FIG. 1 to the orientation shown in FIG. 9. The support portion 18 of the trigger arm 19 moves upward so that the central portion of the trigger arm 19 abuts against the tip of the plunger 17 of the activation switch 10. As a result, the plunger 17 serves as a fulcrum so that force from the support portion 18 presses the other end 19 a of the trigger arm 19 down against the upper end 12 a of the safety portion 12. However, the upper end 12 a remains in place because the upper surface 2 b of the clasp 2 prevents the safety portion 12 from moving. Therefore, the upper end 12 a serves as a fulcrum so that force from the support portion 18 presses the central portion of the trigger arm 19 upward against the plunger 17 when the trigger 11 is pulled. When the plunger 17 is pressed in, the activation switch 10 is turned ON, thereby starting operation of the nail gun 1 so that the nail 4 in the nail ejection portion 5 is driven downward as shown in FIG. 10.
The above explanation is for the situation wherein the trigger 11 is pulled after the nail tip 4 c protruding from the nail ejection hole 5 a was set in the clasp hole 2 a. Next, with reference to FIGS. 11 to 13, an explanation will be provided for operations performed when the nail tip 4 c is not set in the clasp hole 2 a, that is, when the nail ejection port is not located in abutment with a work piece.
In the same manner as described above, when the trigger 11 is pulled in this case, the support portion 18 of the trigger arm 19 moves so that the central portion of the trigger arm 19 abuts against the tip of the plunger 17. Accordingly, the tip of the plunger 17 functions as a fulcrum so that force from the support portion 18 presses the other tip 19 a of the trigger arm 19 down against the upper end 12 a. However, because there is no work piece to prevent downward movement of the safety portion 12 in this case, the safety portion 12 moves from its upper dead center to its lower dead center against the urging force of the spring 15. The plunger 17 remains positioned at its lower dead center so the activation switch 10 does not turn ON.
As the safety portion 12 moves from its upper dead center to its lower dead center, the cam member 21 moves downward with the upper safety portion 20. As shown in FIG. 12, the two guide protrusions 21 b provided on the side surface of the cam member 21 are fitted in the guide grooves 5 b provided on the outer side of the nail ejection portion 5. Therefore, the cam member 21 follows the slanted shape of the guide grooves 5 b in association with downward movement of the guide protrusions 21 b in the guide grooves 5 b and pivots on the pivot shaft 20 a. As shown in FIG. 11, when the safety portion 12 moves downward to near its lower dead center, the cam member 21 separates from the lower safety portion 22. Described in more detail, the lower end 21 a of the cam member 21 pulls away from the lower plate 22 c of the engagement recess portion 22 a, but remains in contact with the upper plate 22 b. The downward urging force of the spring 25 urges the upper plate 22 b into abutment with the lower end 21 a of the cam member 21. At this time, the lower end 12 b protrudes beyond the nail tip 4 c. In this situation, if the lower end 12 b is pressed against a work piece, or for some other reason the lower safety portion 22 is raised upward from its lower dead center, then all that will happen is that as shown in FIG. 13 the lower safety portion 22 will move upward against the urging force of the spring 25. That is, neither the cam member 21 nor the upper safety portion 20 will move upward. Accordingly, activation switch 10 will not be turned ON, because the trigger arm 19 will not be raised upward.
According to the present embodiment, no other components besides the trigger arm 19 are provided within the trigger 11 and supported pivotably on the trigger 11. Moreover, when the safety portion 12 can move into its lower dead center without obstruction, the plunger 17 serves as a fulcrum when the other tip 19 a of the trigger arm 19 presses the upper safety portion 12 a down toward its lower dead center. With this configuration the safety portion 12 can have a long stroke, that is, the safety portion 12 moves a long distance from its upper dead center into its lower dead center. Therefore, the lower end 12 b of the safety portion 12 can be raised up further above the nail tip 4 c, thereby making it easier to visually confirm the position of the nail tip 4 c so that the nail will be driven into the work piece with greater positional accuracy.
Also, because the trigger arm 19 pivots with the tip of the plunger 17 serving as a fulcrum, the force at which the safety portion 12 can be pressed downward can be increased. As a result, the following effects can be achieved. It will be possible to move the safety portions 20, 22 downward, even if the safety portions 20, 22 become difficult to move downward because dirt and the like cling to the safety portions 20, 22, the cam member 21, or other components. This enhances reliability of the nail gun. Also, the safety portions 20, 22 can be reliably lowered, even if the load on the spring 15, which is for supporting the safety portions 20, 22 in the upper dead center, is increased because the weight of the safety portions 20, 22 is increased for some reason, for example to increase the strength of, or to lengthen, the safety portions 20, 22.
Next, a second embodiment will be explained while referring to FIGS. 14 to 16. According to the second embodiment, a safety portion 120 includes an upper safety portion 200, a lower safety portion 220, and a connector 30. The upper safety portion 200 and the lower safety portion 220 are formed with holes 200 e and 220 e, respectively The connector 30 is slidably engaged in the holes 200 e, 220 e, thereby connecting the safety portions 200, 220 together. The connector 30 includes pins 31 on its inside tip. Downward slanting grooves 5 e are formed in the inner surfaces of the nail ejection portion 5. The pins 31 are fitted in the grooves 5 e.
When the safety portion 120 is in its upper dead center as shown in FIG. 14, the safety portions 200, 220 are connected together by the connector 30, and so move vertically in an integral manner. However, when the lower safety portion 220 moves downward without obstruction, the pin 31 slides inward following the guide groove 5 e. Once the safety portions 200, 220 move downward by a predetermined amount or more, then as shown in FIG. 15 the connector 30 pulls out of the hole 220 e of the lower safety portion 220. As a result, there is no danger that the nail gun will fire. Also, even if after this the lower safety portion 220 is raised upward for some reason, then as shown in FIG. 16 the lower safety portion 220 alone will merely move vertically. Again, there is no danger that the nail gun will fire.